Generator load control

ABSTRACT

A power system for an electrical system with highly fluctuating loads is powered by one or more power sources that are slow to react to load changes. The power sources are connected to electrical equipment used on the drill rig which provide active load to the generate. One or more load banks may be positioned to provide passive load to the generators to maintain generally constant generator load, while allowing for instant access to power as active load increases. Generators may be run at  100 % capacity, a maximum efficient capacity, or at a high enough level to allow for a sufficiently rapid increase in power output. At least one parameter of a drilling operation may be utilized to anticipate load demand changes.

CROSS REFERENCE TO RELATED APPLICATIONS

This application is a non-provisional application which claims priorityfrom U.S. provisional application No. 61/935,472 filed Feb. 4, 2014 andU.S. provisional application No. 62/010,652 filed Jun. 11, 2014.

TECHNICAL FIELD/FIELD OF THE DISCLOSURE

The present disclosure relates generally to electric power transmissionfrom a power source to a time-variant load, and specifically to poweringelectrical systems with highly fluctuating loads from one or more powersources that are slow to reset to load changes.

BACKGROUND OF THE DISCLOSURE

In a modern drilling rig, much of the associated equipment is drivenelectrically. For some drilling rigs, generators are used to supplyelectricity to the drilling rig. In general, generators are mostefficient when producing power within a certain range of power output.During drilling operations, electric loads may vary greatly depending onwhat is happening at the rig at any given time. Electrical equipment,including drawworks, mud pumps, top drives, rotary tables, etc. mayconsume large amounts of power when is use. Because each piece ofequipment is used intermittently, the power drawn by the drilling rigmay vary greatly at different times, at times going from very high tovery low in short intervals. At other times, very little power isconsumed by the drilling rig equipment. Additionally, a rapid decreasein electric load may cause a power spike which may cause the rig andgenerator to automatically shut down.

SUMMARY

The present disclosure provides for a power system for running anelectrically driven device using a power load defining an active loadwhen m operation. The power system may include a generator having aminimum efficient load rating. The power system may also include a loadbank electrically coupled to the generator and positioned to provide apower load defining a passive load on the generator when engaged. Thepower system may also include a controller positioned to engage the loadbank and activate the passive load.

The present disclosure also provides for a method for controlling a loadbank. The method may include providing a power system for running one ormore electrically driven devices using a power load defining an activeload when in operation. The power system may include one or moregenerators. Each generator may have a minimum efficient load rating.Each generator may be electrically coupled to the electrically drivendevice. The power system may farther include the load bank. The loadbank may be electrically coupled to the generator and positioned toprovide a power load defining a passive load on the generator whenengaged. The power system may also include a controller positioned toengage the load bank and activate the passive load. The method may alsoinclude calculating the minimum total load of the one or moregenerators; calculating a total power demand of the one or moreelectrically driven devices; calculating, from the minimum total loadand the total power demand, a load bank power demand; and engaging theload bank with the controller to provide passive load to the generatorsgenerally equal to the load bank power demand.

BRIEF DESCRIPTION OF THE DRAWINGS

The present disclosure is best understood from the following detaileddescription when read with the accompanying figures. It is emphasizedthat, in accordance with the standard practice in the industry, variousfeatures are not drawn to scale. In fact, the dimensions of the variousfeatures may be arbitrarily increased or reduced for clarity ofdiscussion.

FIG. 1 is a block diagram of a drilling rig electrical system consistentwith embodiments of the present disclosure.

FIG. 2 is a power flow diagram of the drilling rig electrical system ofFIG. 1.

FIG. 3 is a block diagram for a control system for a resistor bankconsistent with embodiments of the present disclosure.

FIG. 4 is a graph of power consumption in a typical tripping operationfor a drilling rig electrical system consistent with embodiments of thepresent disclosure.

DETAILED DESCRIPTION

It is to be understood that the following disclosure provides manydifferent embodiments, or examples, for implementing different featuresof various embodiments. Specific examples of components and arrangementsare described below to simplify the present disclosure. These are, ofcourse, merely examples and are not intended to be limiting. Inaddition, the present disclosure may repeat reference numerals and/orletters in the various examples. This repetition is for the purpose ofsimplicity and clarity and does not in itself dictate a relationshipbetween the various embodiments and/or configurations discussed.

In some embodiments, a drilling rig power system is powered by one ormore electric generators. The electric generators power electricalequipment on the drilling rig, as well as other electrical systems.Electrical equipment may include, for example and without limitation,drawworks, mud pumps, top drives, rotary tables, power tongs, pipespinners, hydraulic pumps for hydraulic systems, etc. Auxiliaryelectrical systems may include without limitation, lights, computersystems, control systems, HVAC units, one or more LNG skids, etc. Aswould be understood by one having ordinary skill in the art with thebenefit of this disclosure, these auxiliary electrical systems, unlikethe electrical equipment, may generally draw a relatively constant andtime-invariant amount of electric power.

FIG. 1 depicts drilling rig electrical system 100 consistent withembodiments of the present disclosure. Generators 101 may be driven byengines 103. In some embodiments, engines 103 may be driven by liquefiednatural gas. Generators 101 may supply power through supply lines 105 tosupply electrical power to drilling rig electrical system 100. In someembodiments, auxiliary electrical systems 106 may be coupled directly tosupply lines 105 as their power demand may remain relatively constant.In some embodiments, the power supplied by generators 101 is rectifiedby one or more rectifiers 108. In FIG. 1, rectifiers 108 are depicted assingle diodes, but one having ordinary skill in the art with the benefitof this disclosure will understand that any suitable rectifierarrangement may be used, including without limitation, half bridge, fullbridge, single or multiphase, etc. The output electricity, coupled to DCpower bus 110, may then be used to power the electrical equipment. Theelectrical equipment electrically loads generators 101. The load on thegenerators caused by the electrical equipment is referred to herein as“active load”.

In some embodiments, as depicted in FIGS. 1, 2, the electrical equipmentmay include mud pumps 107, drawworks 109, and top drive 111. In someembodiments, each piece of electrical equipment may be powered by acorresponding inverter 113 capable of being controlled by one or morevariable frequency drive (VFD) controllers 115 a, 115 b. In FIG. 1, twoVFD controllers 115 a, 115 b are depicted, separated between power house117 and driller's cabin 119. One having ordinary skill in the art withthe benefit of this disclosure will understand that a drilling rig neednot include power house 117 or driller's cabin 119. Furthermore,although two VFD controllers 115 a, 115 b are depleted, one havingordinary skill in the art with the benefit of this disclosure willunderstand that one or more VFD controllers 115 may be used to controlthe plurality of inverters 113. Inverters 113 are depicted as choppers,but one having ordinary skill in the art with the benefit of thisdisclosure will understand that any other suitable electronic componentor circuit may be substituted within the scope of this disclosure. Forexample, for a three-phase AC motor, the corresponding inverter 113would be a three phase inverter and may be controlled by a pulse widthmodulated (PWM) signal supplied by a corresponding VFD controller 115 asunderstood in the art. Alternatively, for a DC motor, inverter 113 maybe driven by a silicon controlled rectifier (SCR) drive to supplyvariably voltage controlled by the SCR to provide DC power to the motor.

In some embodiments system programmable logic controller (PLC) 121 maybe utilized to control one or more elements of drilling rig electricalsystem 100. As depicted in FIG. 1, PLC 121 is positioned to control VFDcontroller 115 a and generator controller 123. Generator controller 123may control the power output of generators 101 by, for example, varyingthe power output of engines 103 to maintain the proper speed.

As understood in the art, electrical equipment such as mud pumps 107,drawworks 109, and top drive 111 may use large amounts of power when inoperation. During a drilling operation, however, each piece ofelectrical equipment is used in a discontinuous manner causing theactive load on generators 101 to vary in time. For example, during anormal (simplified) tripping-out operation, drawworks 109 may be used tolift a pipe string using a pipe elevator, thus consuming a large amountof power supplied through its corresponding inverter 113 as controlledby VFD controller 115 b. Drawworks 109 then stops, consuming little orno power, as the upper pipe stood is removed from the pipe string.Drawworks 109 then lowers the elevator to engage the top of the pipestring and repeat the process. While lowering, if regenerative ordynamic braking is used, drawworks 109 may return power to drilling rigelectrical system 100. Thus, the active load on generators 101 may varygreatly during the course of drilling operations. Additionally, when theactive load is varied rapidly, generators 101 may not be able to supplyenough power, causing a potential blackout as electrical equipment mayshut off when insufficient power is available. Likewise, voltage spikesmay be damaging for electrical equipment or generators 101 themselves.

To regulate the power level of drilling rig electrical system 100, insome embodiments, generator controller 123 may lower the output power ofgenerators 101 by reducing the fuel supplied to engines 103 or reducingexcitation to generator 101. In some embodiments, generator controller123 may shut down one or more of generators 101 depending on current rigconditions.

Generators 101 may operate most efficiently when producing a certainrange of electrical power. Likewise, generators 101 may operate mostefficiently when electrically loaded. Thus, there may be a lower limitto the power output capable of being produced efficiently by generators101 and a lower limit on electrical loading to allow generators 101 tooperate efficiently or safely. Additionally, because starting up andshutting down generators 101 may require a large amount of time and/orfuel, it may be inefficient to entirely power down one or moregenerators 101 during normal drilling operations. Furthermore, becausethe active load may rapidly increase due to, for example, the use ofdrawworks 109 in the different steps of the tripping operation describedabove, the time required to change the power output of engines 103 tovary the power output of generators 101 may result in insufficient poweravailability to drawworks 109.

The power output of engines 103 may be controlled by varying the amountof fuel supplied to the engine to maintain the speed of generators 101.However, engines 103, including engines 103 powered by LNG or pipelinegas, may not be able to respond quickly enough to maintain generatorspeed with rapid changes in active load. Changes in the amount of fuelprovided to the engine may be slowed by, for example, fuel travellingthrough fuel lines, compressing larger amounts of fuel, andrevaporization of the fuel for the engine. Engines 103 may, asunderstood in the art, be able to more rapidly change in power output ifalready running over a certain load level. In some embodiments of thepresent disclosure, generators 101 may be operated at a relativelyconstant power output, at or near the minimal efficient power outputlevel. In such embodiments, the engine may thus be more able to copewith rapid increases in active.

In some embodiments, the generators may be operated at a power outputlevel corresponding with maximum power output efficiency as dictated bythe design and specifications of the generators. In some embodiments,the generators may be operated at maximum power output to, for example,maximize the instantaneous power available to the drilling rig.

In some embodiments, to maintain generally even power load to generators101 or to reduce load fluctuations, one or more load banks 125 may beconnected to generators 101. In some embodiments, load banks 125 may beelectrically coupled to generators 101 through load bank inverters 127.In some embodiments, inverters 127 may be choppers as understood in theart and may be connected to DC power bus 110. In some embodiments,inverters 127 may be AC converters coupled to an AC power bus. Loadbanks 125 may, as understood in the art, be positioned to dissipateelectric power produced by generators 101, by adding so called “passiveload” to the generator power supply. Although not directly used bydrilling rig electrical system 100 during a drilling operation as is theother electrical equipment, the passive load may be utilized to balancechanges in active load. Thus, generators 101 may operate under generallyconstant loading and load fluctuations may be minimized. In someembodiments, load banks 125 may include resistive elements as shown inFIG. 1, positioned to provide passive load by converting electric powerto heat. In other embodiments, load banks 125 may be any other loadbank, including, for example and without limitation, load banks 125adapted to apply one or more of resistive load, inductive load, liquidload (provided by, for example, a pump and a choke), wind resistanceload, regenerative load (which may supply power to a separate grid suchas the utility grid), capacitive load, or inertial load (such as aflywheel), used to power a motor/generator set, or used to charge abattery. VFD controller 115 a, controlled by PLC 121, controls load bankinverters 127 to provide passive load to generators 101 by supplyingelectrical power to load banks 125, thus allowing generators 101 tooperate at an efficient power output regardless of active load fromother electrical equipment on the drilling rig by adding passive load.Additionally, any negative active load, such as power generated bydynamic braking of drawworks 109, may likewise be dissipated by loadbanks 125.

In some embodiments which utilize a resistive element in load banks 125,total power dissipated by load banks 125 may be given by the followingequation:

$\begin{matrix}{{P_{d} = {3 \cdot N_{B} \cdot M \cdot \frac{V_{d\; c}^{2}}{R}}},} & (1)\end{matrix}$

where P_(d) is the power dissipated as passive load, N_(B) is the numberof three phase load banks, R is the per-phase resistance, and M is theduty cycle which varies between 0 and 1. As understood in the art, dutycycle refers to the fraction of time the load banks are on in a PWMcontrol system. The PWM control system thus allows load banks 125 toproportionately dissipate any power level between 0-100% of their fullpower dissipation capability. In an exemplary drilling rig electricalsystem 100, each load bank 125 may include three 2Ω resistors each witha power rating of 300 kW and 400 kW peak. The continuous rating for eachload bank 123 is thus 900 kW, and peak of 120 kW. If three load banks125 are included in drilling rig electrical system 100, the totalcontinuous and peak dissipation ratings are thus 2.7 MW and 3.6 MWrespectively. One having ordinary skill in the art with the benefit ofthis disclosure will understand that a similar equation may beformulated for any other type of load bank, and the power dissipated aspassive load will likewise depend on the duty cycle.

As an example, during operation, the voltage on DC bus 110 may be, forexample, 780V. According to equation (1), load banks 125 may thusprovide between zero and 2737 kW of power dissipation. Thus, fordrilling rig electrical system 100 including three generators 101, theminimum efficient load rating for each generator 101 may be up toapproximately 900 kW.

The additional power generated by dynamic braking of drawworks 109 aspreviously described, however, may also be dissipated through load banks125. The total generator load may thus be calculated by the followingequation:

L _(G,Total) =P _(d) +L _(aux) −P _(DW),   (2)

where L_(G,Total) is the total generator load, L_(aux) is the load ofauxiliary electrical systems 106, and P_(DW) is the power generated bydrawworks 109 during dynamic braking. Equation (2) may be used todetermine the maximum power that may be regenerated by drawworks 109while maintaining the minimum efficient load rating for generators 101,maintaining a generally constant load on generators 101. Depending onthe number of active generators 101, it may be necessary to operatedrawworks 109 at a lower ramp rate on deceleration to ensure the maximumregenerated power is not exceeded.

In some embodiments, PLC 121 or a separate controller may determine theamount of passive load to apply with load banks 125. As depicted in FIG.3, total minimum generator load 201 may be calculated by multiplying theminimum generator load 203 by the number of generators online 205.Actual generator loads 207, as supplied by the generator controller, aresubtracted from total minimum generator load 201 to create adifferential power error signal to be used by controller 209 tocalculate minimum DC link power 211. Controller 209 may be part of PLC121 or a separate controller. Minimum DC link power 211 may be limitedby limiter 213 between a value of zero and total minimum generator load210. Additionally, minimum DC link power 211 may be fed into controller209 to, for example, prevent windup as understood in the art. In someembodiments, the maximum load change able to be handled by drilling rigelectrical signal 100 may be fed into controller 209 as well.

Total power demand 214 which corresponds to the active load may becalculated as the sum of the power demands for each piece of electricalequipment. The power demands include mud pump power demand 215 a-b, topdrive power demand 217, and drawworks power demand 219 a-b. Aspreviously discussed, drawworks power demand 219 a-b may be negativeduring dynamic braking.

In some embodiments, controller 209 may be a proportional integralderivative (PID) controller. One having ordinary skill in the art withthe benefit of this disclosure will understand that controller 209 maybe any controller capable of operating as described including, withoutlimitation, a step change controller, a state controller, a proportionalcontroller (P), a proportional integral controller (PI), a PIDcontroller, a proportional derivative controller (PD), an adaptivecontroller, or a predictive controller. In certain embodiments,anticipated load change may be based on process variables in addition toactual generator load to form a multi-variable control system. In someembodiments, additional process variables may include operationalparameters, including, for example and without limitation, depth ofwellbore, hook load, pump pressure, pump rate, length of drill string,and weight on bit, as well as any changes or requested changes thereto.In some embodiments, additional process variables may include powergeneration and distribution parameters, including, for example andwithout limitation, increase or change in current, increase or change inpower, and number of engines online, as well as any requested changesthereto. As a non-limiting example, it may be anticipatable that adrilling bit at a greater depth may result in a larger top drive powerdemand 217. As another example, a longer drill string may result in alarger drawworks power demand 219 a-b during, for example, a trippingoperation. By incorporating an anticipated load into total power demand214, the response time for controller 209 may, for example, be improved.

Total power demand 214 may be subtracted from minimum DC link power 211to determine load bank power demand 221 or the amount of passive load toadd to the system. Additionally, any auxiliary load may also besubtracted as well. Load bank power demand 221 may then be used tocalculate (at 223) load bank duty cycle 225 according to the followingequation, derived from Equation 1 above:

$\begin{matrix}{M = {\frac{P_{d} \cdot R}{3 \cdot N_{B} \cdot V_{d\; c}^{2}}.}} & (3)\end{matrix}$

FIG 4 depicts power flow during an exemplary tripping cycle aspreviously discussed. Any values depicted are shown for exemplarypurposes only and are not intended to be limiting in any way. Depictedis generator power 301 (dotted line), load bank power 303 (solid line),and drawworks power 305 (dashed line) over time. Auxiliary load isassumed to be a constant 300 kW, and no power is going to any otherelectrical equipment. Additionally, drawworks dynamic braking power islimited to 1.5 MW.

From time 0 to time 22, the drawworks is lifting the drill string. Thedrawworks is utilizing 1900 kW, while the generators provide 2200 kW.The 300 kW difference is consumed by the auxiliary load, and thus theload banks are dissipating no power. At time 22, the drawworks arestopped, causing a large negative inductive power spike and a negative(regenerative) load during the slow-down of the drawworks. The loadbanks are activated, in some embodiments at a 100% duty cycle, todissipate the power spike. In some embodiments, generator power outputmay be reduced to the minimum efficient power output, here 1500 kW. Ifthe load banks were not activated, negative power from the drawworks mayover speed the generators. Such an event may trigger a generator safetycircuit which would shut the generators off, thus causing a “black-out”.

Once the inductive spike is dissipated and the drawworks has stopped,the load banks are used to dissipate excess power from the generators.The load bank duty cycle is calculated such that the load banksdissipate 1200 kW.

At time 70, the drawworks are beginning to lower the elevator, causing apositive inductive power spike followed by a period of negative powerlasting until the drawworks is stopped. The load banks are deactivated,and the output of generators is increased to supply sufficient power toabsorb the inductive spike. After the spike, as the drawworks lower,dynamic braking thereof generates 300 kW of power. The load bank dutycycle is modified so that the load banks dissipate 1500 kW of power. Thedrawworks are then stopped, again causing a large negative inductivespike, again dissipated by the load banks. Thus after time 90, thedrawworks are drawing no power, the generators generating 1500 kW, andthe load banks dissipating 1200 kW, again the difference between thegenerator output and the auxiliary load.

The foregoing outlines features of several embodiments so that a personof ordinary skill in the art may better understand the aspects of thepresent disclosure. Such features may be replaced by any one of numerousequivalent alternatives, only some of which are disclosed herein. One ofordinary skill in the art should appreciate that they may readily usethe present disclosure as a basis for designing or modifying otherprocesses and structures for carrying out the same purposes and/orachieving the same advantages of the embodiments introduced herein. Oneof ordinary skill in the art should also realize that such equivalentconstructions do not depart from the spirit and scope of the presentdisclosure and that they may make various changes, substitutions, andalterations herein without departing from the spirit and scope of thepresent disclosure.

1. A power system for running an electrically driven device using apower load defining an active load when in operation comprising: agenerator, the generator having a minimum efficient load rating, thegenerator electrically coupled to the electrically driven device; a loadbank, the load bank electrically coupled to the generator and positionedto provide a power load defining a passive load on the generator whenengaged; and a controller positioned to engage the load bank andactivate the passive load.
 2. The power system of claim 1, wherein theload bank is adapted to provide one or more of a resistive, inductive,liquid, wind resistance, regenerative, inertial, or capacitive load orto provide load to charge a battery or to run a motor/generator set. 3.The power system of claim 1, wherein the load bank is electricallycoupled to the generator via an inverter, the inverter being controlledby the controller to increase or decrease the amount of passive loadconnected to the generator.
 4. The power system of claim 3, wherein theinverter is coupled to a variable frequency drive, the variablefrequency drive having a DC link, so that the load bank draws power fromthe DC link.
 5. The power system of claim 3, wherein the inverter isdriven by a PWM signal sent by the controller, and the passive load isdetermined by the duty cycle of the inverter.
 6. The power system ofclaim 5, wherein the duty cycle of the PWM signal proportionallycontrols the passive load of the load bank from 0-100% of the loadcapability of the load bank.
 7. The power system of claim 5, wherein theload bank further comprises one or more three phase resistive loadbanks, and the duty cycle is calculated according to:${M = \frac{P_{d} \cdot R}{3 \cdot N_{B} \cdot V_{d\; c}^{2}}},$ whereP_(d) is the power dissipated, N_(B) is the number of load banks, R isthe per-phase resistance of the three phase resistive load banks, and Mis the duty cycle of the inverter.
 8. The power system of claim 1,wherein the electrically driven device is an electric motor capable ofdynamic braking, and the power generated thereby is dissipated by theload bank.
 9. The power system of claim 3, wherein the invertercomprises a chopper.
 10. The power system of claim 1, wherein thecontroller is a step change controller, a state controller, aproportional controller, a proportional integral controller, aproportional integral derivative controller, a proportional derivativecontroller, an adaptive controller, or a predictive controller.
 11. Thepower system of claim 10, wherein a process variable for the controlleris actual generator power load.
 12. The power system of claim 11,comprising an additional variable for the controller selected from thegroup consisting of depth of wellbore, hook load, pump pressure, pumprate, length of drill string, weight on bit, increase or change incurrent, increase or change in power, and number of engines online, orany changes or requested changes thereto.
 13. A method for controlling aload bank comprising: providing a power system for running one or moreelectrically driven devices using a power load defining an active loadwhen in operation, the power system including: one or more generators,each generator having a minimum efficient load rating, each generatorelectrically coupled to the electrically driven device; the load bank,the load bank electrically coupled to the generator and positioned toprovide a power load defining a passive load on the generator whenengaged; and a controller positioned to engage the load bank andactivate the passive load; calculating the total minimum generator loadof the one or more generators; calculating a total power demand of theone or more electrically driven devices; calculating, from the totalminimum generator load and the total power demand, a load bank powerdemand; and engaging the load bank with the controller to providepassive load to the generators generally equal to the load bank powerdemand.
 14. The power system of claim 13, wherein the load bank isadapted to provide one or more of a resistive, inductive, liquid, windresistance, regenerative, inertial, or capacitive load or to provideload to charge a battery or to run a motor/generator set.
 15. The methodof claim 13, wherein the load bank is electrically coupled to thegenerator via an inverter, the inverter being controlled by thecontroller to selectively connect and disconnect the load bank from thegenerator.
 16. The method of claim 15, wherein the inverter is coupledto a variable frequency drive, the variable frequency drive having a DClink, so that the load bank draws power from the DC link.
 17. The methodof claim 15, wherein the inverter is driven by a PWM signal sent by thecontroller, and the passive load is determined by the duty cycle of theinverter.
 18. The method of claim 17, wherein the duty cycle of the PWMsignal proportionally controls the passive load of the load bank from0-100% of the load capability of the load bank.
 19. The method of claim17, wherein the load bank further comprises one or more three phaseresistive load banks, and the duty cycle is calculated according to:${M = \frac{P_{d} \cdot R}{3 \cdot N_{B} \cdot V_{d\; c}^{2}}},$ whereP_(d) is the power dissipated as passive load, N_(B) is the number ofload banks, R is the per-phase resistance of the three phase load banks,and M is the duty cycle of the inverter.
 20. The method of claim 13,wherein the output power of the one or more generators is controllableby the controller, and the method further comprises: controlling thepower output of the one or more generators based on the total powerdemand.
 21. The method of claim 13, wherein a process variable for thecontroller is actual generator load.
 22. The method of claim 21,comprising an additional variable for the controller selected from thegroup consisting of depth of wellbore, hook load, pump pressure, pumprate, length of drill string, weight on bit, increase or change incurrent, increase or change in power, and number of engines online, orany changes or requested changes thereto.